KR20190133919A - Temperature monitoring apparatus and system for high-voltage wiring lines - Google Patents

Abstract

The present invention provides a temperature monitoring apparatus for a high-voltage wiring line and a system thereof which prevent degradation due to overload. According to the present invention, the temperature monitoring apparatus comprises: a sensor unit installed in a protection wall in a distributing board having the protection wall to measure the inside temperature of the protection wall; a transmission unit to transmit the measured temperature from the sensor unit to a gateway installed on the distributing board; a power generation unit having a coil and generating power by electromagnetic induction with the coil and a busbar of the distributing board; and a control unit to allow the power to be generated in real time, drive the sensor unit by the generated power to measure temperature, and transmit measured temperature information to the gateway.

Description

Temperature monitoring apparatus and system for high-voltage wiring lines

The present invention relates to a temperature monitoring device, and more particularly, to a temperature monitoring device and system for a high voltage wiring line that prevents the occurrence of deterioration due to overload by real-time monitoring the temperature inside the protective wall of the switchboard.

In general, a switchboard is a facility that receives electric power from KEPCO and converts it into electric power that can be used by consumers through a transformer and distributes power to individual loads.

Inside the switchboard, power devices such as switchgear, power fuse, instrument transformer, and breaker are electrically connected by bus bar and cable, and bolt loosening, contact resistance, etc. in the contact area where power devices are connected by bus bar and cable. It is known that the most temperature rise occurs as a cause.

In particular, the temperature rise inside the protective wall to minimize the damage caused by the electrical explosion of the switchboard has a problem that is difficult to detect from the outside due to the protective wall.

Korean Patent Publication No. 10-1264344 (2013.05.08.)

It is an object of the present invention to provide a temperature monitoring device and system for a high voltage wiring line which prevents deterioration due to overload by real-time monitoring the temperature of the inside of a protective wall of a high voltage wiring line switchboard.

In order to achieve the above object, the high-voltage wiring line temperature monitoring apparatus according to the present invention is installed inside the protective wall of the switchboard having a protective wall is a sensor unit for measuring the temperature inside the protective wall, the temperature measured from the sensor unit A transmitter configured to transmit to a gateway installed in a switchboard, a coil, a power generator configured to generate power by electromagnetic induction with the coil and a busbar of the switchboard, and the power to be generated in real time, and the sensor to the generated power. It includes a control unit for driving the unit to measure the temperature, and transmits the measured temperature information to the gateway.

The apparatus may further include a power control unit connected to the power generation unit and configured to constantly correct power generated by the power generation unit to a predetermined size of power.

In addition, the transmitting unit is characterized in that provided in the interior of the protective wall or the outside of the protective wall.

In addition, when the transmitter is installed inside the protective wall, it is characterized in that it further comprises a housing formed of a material that is insulated and insulated, and formed to be provided in the transmitter and the power generator.

In addition, the housing, the lower portion is coupled to the busbar, the power generation unit is provided on the upper portion of the busbar, characterized in that the transmission unit is provided on the upper portion of the power generation unit.

In addition, when the transmission unit is installed outside the protective wall, and further comprises a signal line passing through the protective wall between the sensor unit and the transmitting unit, and transmits the temperature information measured from the sensor unit to the transmitting unit. do.

In addition, the transmitting unit is connected to the signal line, characterized in that formed in the form of a patch (patch) attached to the busbar.

The temperature monitoring system according to the present invention measures an internal temperature of a switchboard, receives a temperature monitoring device for monitoring the switchboard by using the measured internal temperature and the monitored information from the temperature monitoring device, and receives the received information. And managing a temperature state of the switchboard by using the control server to cut off the power of the switchboard when it is determined that the temperature state is abnormal. The temperature monitoring device is installed inside the protective wall of the switchboard and is inside the protective wall. A power generation unit including a sensor unit measuring a temperature of the sensor unit, a transmitter unit transmitting a temperature measured from the sensor unit to a gateway installed in the switchboard, and generating a power source with electromagnetic induction between the coil and the busbar of the switchboard. And allowing the power to be generated in real time, The and by actuating the said sensor measuring the temperature of the power source, characterized by comprising a control section for transmitting the measured temperature information to the gateway.

Temperature monitoring apparatus and system for a high voltage wiring line of the present invention can monitor the temperature inside the protective wall by measuring the temperature in real time by providing a sensor unit inside the protective wall of the switchboard for high voltage wiring line.

In addition, the sensor unit and the transmitter may be driven by generating power through electromagnetic induction using busbars and coils of the switchboard, without providing a separate power supply device.

1 is a configuration diagram illustrating a temperature monitoring system according to an embodiment of the present invention.
2 is a block diagram illustrating a temperature monitoring apparatus according to an embodiment of the present invention.
3 is a schematic view for explaining a switchboard and a temperature monitoring apparatus according to an embodiment of the present invention.
4 is a view for explaining a contact portion located inside the protective wall according to an embodiment of the present invention.
Figure 5 is a perspective view for explaining the outside of the housing according to the embodiment of the present invention.
6 is a cross-sectional view for explaining the interior of the housing according to the embodiment of the present invention.
7 is a schematic view for explaining a temperature monitoring apparatus according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it is noted that the same reference numerals are assigned to the same components as much as possible, even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function is apparent to those skilled in the art or may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a configuration diagram illustrating a temperature monitoring system according to an embodiment of the present invention.

Referring to FIG. 1, the temperature monitoring system 500 prevents deterioration due to overload by real-time monitoring the temperature of the inside of the protective wall of the switchboard 200 for the high voltage wiring line. The temperature monitoring system 500 includes a temperature monitoring device 100 and a management server 300.

The temperature monitoring apparatus 100 is installed in the switchboard 200 and monitors the temperature of the inside of the switchboard 200 in real time. At this time, the switchboard 200 is provided with a protective wall to minimize the electrical explosion. The temperature monitoring apparatus 100 may monitor a temperature inside the switchboard 200 by measuring temperatures of the inside and the outside of the protective wall. That is, the temperature monitoring device 100 may monitor the temperature of the entire inside of the switchboard 200 by measuring the temperature of the outside and the inside of the protection wall, unlike the existing temperature monitoring device measuring only the temperature of the outside of the protection wall. . Through this, the temperature monitoring apparatus 100 may perform monitoring in real time on the inside of the protective wall, which is substantially higher than the outside of the protective wall. In addition, the temperature monitoring apparatus 100 may transmit the monitored information to the management server 300.

The management server 300 receives the monitoring information from the temperature monitoring device 100, and manages the temperature state of the switchboard 200 using the received information. At this time, the management server 300 may cut off the power of the switchboard 200 if it is determined that the temperature is abnormal. Through this, the management server 300 can prevent the explosion due to the electrical deterioration of the switchboard 300 in advance.

On the other hand, the temperature monitoring system 500 establishes a communication network 400 between the temperature monitoring device 100 and the management server 300 to enable wireless communication with each other. Here, the communication network 400 may be a local area network, and may be a zigbee, a low power Bluetooth (BLE), a wireless LAN (IEEE 802.11b, IEEE 802.11a, IEEE 802.11g, IEEE 802.11n), and the like. Preferably BLE.

2 is a block diagram for explaining a temperature monitoring apparatus according to an embodiment of the present invention, Figure 3 is a schematic diagram for explaining a switchboard and a temperature monitoring apparatus according to an embodiment of the present invention, Figure 4 is an embodiment of the present invention FIG. Is a view for explaining a contact portion located inside a protective wall according to an example.

1 to 4, the temperature monitoring apparatus 100 includes a power generator 10, a sensor 40, a transmitter 50, and a controller 60, and includes a power controller 20 and a battery ( 30) further includes.

The power generator 10 generates power through electromagnetic induction. To this end, the power generator 10 has a coil. The power generator 10 induces electromagnetic current between the coil and the high current flowing to the bus bar 260 of the switchboard 200. The power generator 10 generates power with a preset size by adjusting the number of coiling times of the coil. Here, the preset size may be the size of the power used in the load.

The power controller 20 is connected to the power generator 10 and constantly corrects the power generated by the power generator 10 to have a predetermined size. That is, the power control unit 20 may compensate for the problem that the power generated by the power generation unit 10 may have an unstable power in the electromagnetic induction process. Through this, the temperature monitoring device 100 can be supplied with a stable power can increase the reliability of the product.

The battery 30 is connected to the power control unit 20 and charges the power output from the power control unit 20. The battery 30 normally maintains a charged state, but supplies a charged power when the generation of the power is temporarily stopped. The battery 30 may be a secondary battery, a supercapacitor, or the like.

The sensor unit 40 measures the temperature of the bus bar installed in the bus bar 260 of the switchboard 200. That is, the sensor unit 40 includes a plurality of temperature sensors. At this time, the sensor unit 40 may install one temperature sensor for each bus bar 260 to measure the temperature of each bus bar 260. The sensor unit 40 may be installed at the contact unit 45 to which the bus bar 260 and the bolt are connected. Preferably, the sensor unit 40 may be installed inside the protection wall 230 as well as outside the protection wall 230 of the switchboard 200 to measure the temperature of the bus bar 260 inside the protection wall. Here, the protective wall 230 is formed between the front door 210 and the rear inner door 220 of the switchboard 200, when the electrical explosion is generated, serves to primarily buffer the explosion debris, explosion shock, etc. Do it.

The transmitter 50 transmits the temperature measured from the sensor unit 40 to the gateway 240 installed in the switchboard 200. Here, the gateway 240 serves as an intermediary for receiving information on the internal temperature of the switchboard 200 and transmitting the received information to an external management server 300. The gateway 240 may be installed inside the front door 210. In addition, an indicator 250 may be installed at a position opposite to the gateway 240 based on the front door 210.

Meanwhile, the transmitter 50 may be installed inside the protection wall 230 or outside the protection wall 230, and a detailed description thereof will be described with reference to FIGS. 6 to 7.

The controller 60 performs control of each component. The controller 60 controls the power generator 10 to control power generation in real time. The controller 60 drives the sensor unit 40 with the generated power, and measures the temperature of the inside of the switchboard 200 through this. The controller 60 transmits the measured temperature information to the gateway. Here, the control unit 60 may be a micro controller unit (MCU).

5 is a perspective view for explaining the outside of the housing according to an embodiment of the present invention, Figure 6 is a cross-sectional view for explaining the inside of the housing according to an embodiment of the present invention.

2 to 6, when the transmitter 50 is installed inside the protective wall 230, the temperature monitoring apparatus 100 may include a housing 70.

The housing 70 is formed of a material that is insulated and insulated, and is formed to include the transmitter 50 and the power generator 10. The housing 70 has a lower portion coupled to the busbar 260, and a power generation unit 10 is provided at the upper portion of the busbar 260. In addition, the housing 70 is provided with a transmitter 50 on the power generation unit 10. Here, the housing 70 has a structure in which the busbar 260, the power generator 10, and the transmitter 50 are stacked, but is not limited thereto.

However, in the housing 70, the busbar 260 and the power generator 10 are disposed adjacent to each other so that the busbar 260 and the power generator 10 perform electromagnetic induction. The transmitter 50 may be disposed so that the transmitted signal does not affect the high current flowing through the busbar 260.

Therefore, the temperature monitoring apparatus 100 may increase the reliability of the transmitter 50 by minimizing an external influence through the housing 70 even when the transmitter 50 is installed inside the protective wall 230.

7 is a schematic view for explaining a temperature monitoring apparatus according to another embodiment of the present invention.

1 and 7, when the transmitter 50 is installed outside the protective wall 230, the temperature monitoring device 150 may include a signal line 80.

The signal line 80 penetrates through the protective wall 230 and connects between the sensor unit 40 and the transmitting unit 90. The signal line 80 transmits the temperature information measured from the sensor unit 40 to the transmitter 90. In this case, the signal line 80 may be in close contact with or attached to the bus bar 260, and preferably may be a material in which an outer coating is insulated and insulated.

The transmitter 90 connected to the signal line 80 may transmit temperature information to the gateway 240, and the gateway 240 may transmit the external management server 300. Here, the transmission unit 90 may be formed in the form of a patch (patch) attached to the busbar 260.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific preferred embodiments described above, and the present invention belongs to the present invention without departing from the gist of the present invention as claimed in the claims. Various modifications can be made by those skilled in the art, and such changes are within the scope of the claims.

10: power generation unit 20: power control unit
30: battery 40: sensor
45: contact portion 50, 90: transmitter
60: control unit 70: housing
80: signal line 100, 150: temperature monitoring device
200: switchboard 210: front door
220: rear inner door 230: protective wall
240: gateway 250: indicator
260: busbar 300: management server
400: network 500: temperature monitoring system

Claims (8)

A sensor unit installed inside the protection wall of the switchboard including the protection wall to measure a temperature inside the protection wall;
A transmitter for transmitting the temperature measured from the sensor unit to a gateway installed in the switchboard;
A power generation unit including a coil and generating power by electromagnetic induction between the coil and the busbar of the switchboard; And
A controller configured to generate the power in real time, measure the temperature by driving the sensor unit with the generated power, and transmit the measured temperature information to the gateway;
Temperature monitoring device for a high voltage wiring line comprising a. The method of claim 1,
A power control unit connected to the power generation unit and configured to constantly correct power generated by the power generation unit to a predetermined power level;
Temperature monitoring device for a high voltage wiring line further comprises. The method of claim 1,
The transmitting unit,
Temperature monitoring device for a high voltage wiring line, characterized in that installed in the inner or the outer wall of the protective wall. The method of claim 3, wherein
When the transmitting unit is installed inside the protective wall, the housing is formed of a material that is insulated and insulated, and formed to be provided inside the transmitting unit and the power generating unit;
Temperature monitoring device for a high voltage wiring line further comprises. The method of claim 4, wherein
The housing,
A lower portion is coupled to the busbar, the power generator is provided on the upper portion of the busbar, the temperature monitoring device for a high voltage wiring line, characterized in that the transmitter is provided on the upper portion of the power generator. The method of claim 3, wherein
A signal line passing through the protective wall to connect the sensor unit and the transmitting unit when the transmitting unit is installed outside the protective wall, and transferring temperature information measured from the sensor unit to the transmitting unit;
Temperature monitoring device for a high voltage wiring line further comprises. The method of claim 6,
The transmitting unit,
The temperature monitoring device for a high voltage wiring line connected to the signal line, characterized in that formed in the form of a patch (patch) attached to the bus bar. A temperature monitoring device measuring an internal temperature of a switchboard and monitoring the switchboard using the measured internal temperature; And
A management server for receiving the monitored information from the temperature monitoring device, managing the temperature state of the switchboard by using the received information, and shutting off the power of the switchboard if it is determined that the temperature state is abnormal. ,
The temperature monitoring device,
A sensor unit installed inside the protection wall of the switchboard and measuring a temperature inside the protection wall;
A transmitter for transmitting the temperature measured from the sensor unit to a gateway installed in the switchboard;
A power generation unit including a coil and generating power by electromagnetic induction between the coil and the busbar of the switchboard; And
A controller configured to generate the power in real time, measure the temperature by driving the sensor unit with the generated power, and transmit the measured temperature information to the gateway;
Temperature monitoring system comprising a.

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